JPH09508769A - Local oscillator phase noise cancellation modulation technology - Google Patents

Abstract

(57) [Summary] The disclosed data transmission system of the present invention includes a signal source for a data signal, a first modulated signal representing the data signal in response to the data signal, and a phase shift of 180 ° with respect to the data signal. A second modulated signal representative of the received signal and a modulator for generating a second modulated signal. The first and second modulated signals are transmitted via the transmission channel. The first demodulator (50) 100) demodulates the transmitted first modulated signal. The second demodulator (50) 100) demodulates the transmitted second modulated signal. The subtractor (60, 70) produces a signal representative of the data signal in response to the first and second demodulators.

Description

Detailed Description of the Invention                   Local oscillator phase noise cancellation modulation technology   The present invention relates to a modulation technique for canceling the phase noise of a local oscillator.                               Background of the Invention   In any data transmission system, the final signal-to-noise ratio or S / N It is desirable to maximize the ratio (SNR). Transmission carrier data transmission The main source of noise limiting the S / N ratio in the system is the transmitter modulator Phase instability of the local oscillator (LO) in both the receiver and the demodulator on the receiver side Is known. Improves final S / N ratio by minimizing phase instability One technique to do this is to use a more precisely controlled local oscillator. this In such a local oscillator, it is necessary to generate a signal with a more stable phase characteristic. Therefore, it uses complex circuits and high quality components as its construction. But, Such local oscillators are costly due to the complicated circuitry and high quality components used. Become. Of course, the cost of such a system is low, especially in consumer electronics. It is desirable to suppress it. Therefore, the need to use expensive and high quality circuits and components The final S / N ratio even in the presence of local oscillator phase instability. Modulation techniques that can be improved are desired.                             Brief summary of the invention   A data transmission system according to the principles of the present invention includes a data signal source and a data signal source. A first modulated signal (modulated signal) representing the data signal and the data in response to the signal. A second modulated signal (modulated signal) that represents a signal that is 180 ° out of phase with the signal. No.) and a modulator for generating. The first and second modulated signals are transmission channels. It is transmitted (transported) via the Internet. The first demodulator is used to transmit the first The key signal is demodulated, and the second demodulator demodulates the transmitted second modulated signal. Subtractor Produces a signal representative of the data signal in response to the first and second demodulators.                             Brief description of the drawings   In the figure,   FIG. 1 is a block diagram of a transmitter according to the present invention,   2 is a frequency diagram of the spectrum produced by the transmitter shown in FIG. 1,   FIG. 3 is a block diagram of a receiver used in connection with the transmitter shown in FIG. You.                             Detailed description of the drawings   FIG. 1 is a block diagram of a data transmitter according to the present invention. In Figure 1, A signal source (not shown) of the data signal x (t) is coupled to the input terminal 5 of the data transmitter. The input terminal 5 is a frequency control input terminal of a voltage controlled rectangular wave oscillator (VCO) 10. Is bound to a child. The output terminal of the VCO 10 is the first input terminal of the mixer 20. The output terminal of the mixer 20 is coupled to the output terminal 15 of the data transmitter. Is bound to. The output terminal 15 is a radio frequency or optical transmission, or The signal at the output terminal 15 is transmitted to the receiver (which will be described in detail later). The near end of the transmit channel, including any other transmission method for transmitting. nd). The transmission carrier local oscillator (LO) 30 is connected to the mixer 20. It is coupled to the second input terminal.   FIG. 2 is a frequency diagram useful in understanding the operation of the transmitter shown in FIG. Frequency f_sThe spectrum of both sidebands of the rectangular wave of_sFundamental wave component and basic Frequency f_sOdd-order harmonic component of, ie, the amplitude gradually decreases ± 3f_s, ± 5f_s ... is known to consist of. Also, the corresponding positive and negative spectra It is also known that the parts are 180 ° out of phase with each other. To explain the operation, The data signal x (t) frequency-modulates the rectangular wave signal generated by the VCO 10. You. Each component of the rectangular wave is an FM carrier modulated by the data signal x (t) Acting, it itself carries all the information from the data signal x (t). FM The maximum frequency shift of the modulation is that the sidebands centering on each rectangular wave component are relatively narrow, and Selected so that they do not overlap each other.   The FM modulated square wave signal containing all of the above sideband components is then mixed by the mixer 20 and the local oscillator 30 transmit the carrier wave f in a known manner._aUpconverter (Converted to high frequency). As shown in FIG. 2, the spectrum Y (f ) Is the frequency f_aIt is at point 2. In the upper sideband, the first energy band 4 is f_a+ F_sAnd the second energy band 6 is f_a+ 3f_sCentered around You. In the lower sideband, the first energy band 7 is f_a-F_sCentered on , The second energy band 9 is f_a-3f_sIs the center. Other energy bands also available Yes, but not shown in the figure. Energy bands 4 and 7, energy bands 6 and 9 180 ° out of phase with each other. This means that energy bands 4 and 6 Is indicated by a "+" sign inside and by a "-" sign in energy bands 7 and 9 You. Signs of "+" and "-" are 18 between signals represented by corresponding frequency bands. Show that there is a phase difference of 0 °, and also show any other absolute arithmetic relation. It does not mean.   The FM-modulated rectangular wave signal consisting of all sideband components (4 to 9 in FIG. 2) is 1 It is up-converted in the mixer 20 as one unit. Therefore, All phase instabilities in the carrier signal generated by oscillator 30 are FM modulated. Each sideband component in the rectangular wave signal is affected in exactly the same manner. Local oscillator 3 Noise caused by any phase instability of 0 causes an FM modulated square wave signal to Appears as a phase modulation of the constituent sidebands. Each sideband component is distributed in a similar manner. Since it is phase-modulated, it will have all the energy in both the upper and lower sidebands. It becomes in-phase in the Gi band (4-9). Modulate due to this phase instability of the local oscillator 30 It causes noise in the signal, that is, the modulated signal, and reduces the S / N ratio. Figure 3 2 is a block diagram of a data receiver corresponding to the transmitter shown in FIG. 1. FIG. In FIG. The far end of the transmission channel (not shown) is the data end. To the input terminal 35 of the receiver. This input terminal 35 is the first terminal of the mixer 20 '. 1 input terminal. The intermediate frequency (IF) local oscillator 30 'is the mixer 2 It is coupled to the second input of 0 '. The output terminal of the mixer 20 'is a bandpass filter ( BPF) circuit 40, which is coupled to the input terminal of the bandpass filter circuit 40. The output terminal is the input of each of the first phase locked loop 50 and the second phase locked loop 100. Coupled to the force terminal. The first phase locked loop 50 is a phase detector 5 having a well-known configuration. 2, a loop filter 54 and a voltage controlled oscillator 56, and a second The phase locked loop 100 of FIG. 04 and the voltage controlled oscillator 106. First phase-locked loop The output terminal of 50 is coupled to the inverting input terminal of adder 60 to provide a second phase lock loop. The output terminal of amplifier 100 is coupled to the non-inverting input terminal of adder 60. Adder 60 Has its output terminal coupled to the input terminal of a low pass filter (LPF) 80. The output terminal of the low pass filter 80 is coupled to the output terminal 45 of the data receiver. You. The output terminal 45 of the data receiver is a circuit for utilizing the transmitted data signal (t) (see FIG. (Not shown).   In operation, the input terminal 35 is the transmitted modulated or modulated signal. (T) is received, and this is sent to the mixers 20 'and f_a-F_bIF local oscillation with frequency of Transmitter carrier frequency f using_aTo the IF frequency f_b Down-convert to (convert to a lower frequency). This down-converted credit The spectrum of the signal is f with the center frequency 2 shown._aInstead of f_bExcept that It is similar to the spectrum shown in FIG. Thus, for example, the sideband 4 IF sideband is f_b+ F_sAnd the IF sideband corresponding to sideband 7 is f_b− f_sThere is a center.   The band pass filter 40 has a center frequency f_bWith sidebands 4 and 7 only It has a bandwidth suitable for As mentioned above, each of these sidebands The data signal x (t) FM-modulated by itself is shown. Phase locked loop 50 The voltage controlled oscillator (VCO) 56 has a center frequency f_b+ F_sAnd the phase lockle The loop 50 detects and demodulates the data signal carried by the upper sideband 4. Rank The voltage controlled oscillator (VCO) 106 of the phase locked loop 100 has a center frequency f_b-F_s And the phase-locked loop 100 has a data signal carried by the lower sideband 7. Signal is detected and demodulated. The adder 60 operates here as a subtractor. Phase lock The detected data signals from croup 50 and phase locked loop 100 are described above. 180 ° out of phase with each other, these data signals are output from the adder 60. Constructive in power, while transmitter side local oscillator (LO) 30 and receiver side local Any phase noise introduced by both oscillators (LO) 30 'is as described above. Since the sidebands 4 and 7 have the same phase, these noise components are added to the output of the adder 60. Will be offset. The low-pass filter 80 is a received data signal with noise cancelled. (T) is generated.   The above system is described as a local oscillator (LO) phase noise cancellation system. However, in order to send 2 data by modifying this system a little Can also be used. In FIG. 1, the source of the second data signal z (t) is the data source. Data input to the second input terminal 25 of the transmitter. The input terminal 25 is shown by a broken line Is connected to the frequency control input terminal of the local oscillator 30 as shown in FIG. The FM signal FM modulates the local oscillator signal. The rest of the transmitter operates in the manner described above. To make. The spectrum obtained by the second FM-modulated data signal is broken in FIG. It is shown with a line. As can be seen, each sideband 4-6 has a second FM modulated second sideband. It is a composite signal including the component 3 of the data signal. The data represented by this component The signals are in phase in all sidebands 4-6. This is shown in FIG. As shown above for the energy bands 4-6, in all energy bands 4-6. And is indicated by a "+" sign in the component 3 of the FM-modulated second data signal. .   The receiver of FIG. 3 operates as described above to cancel the phase noise of the local oscillator, At the same time, the second data signal also produces a canceled data signal (t). Also, the phase Both output terminals of the lock loop 50 and the phase lock loop 100 are indicated by broken lines. And is coupled to each non-inverting input terminal of adder 70. Phase locked loop 50 and And the first data signal from 100 is 180 ° out of phase as described above, , They cancel at the output of adder 70. Phase locked loop 50 and The second data signal from 100 and the phase noise of all local oscillators are in phase Therefore, they will be constructive at the output of the adder 70. Shown with a dashed line As described above, the low-pass filter (LPF) 90 is coupled to the output terminal of the adder 70. And pass the received second data signal (t) and the local oscillator noise component. Let   There is no local oscillator noise cancellation in the second data signal path. Therefore, higher For data signals requiring S / N ratio, it is necessary to use a higher quality local oscillator. It is necessary. Alternatively, this second signal path can be routed to a lower ultimate S / N ratio. Line numbering off [(LINE numbering off (do not delete)] It may be used only for signals that can be used locally.

[Procedure of Amendment] Article 184-8 of the Patent Act [Submission date] November 30, 1995 [Correction contents]                                The scope of the claims 1. A data signal source (5, 25),   A first spectral component representative of the data signal in response to the data signal; , A second spectrum representing a signal that is 180 ° out of phase with the above-mentioned output signal A modulator for producing a modulated signal having a component, and   A transmission channel for transmitting the modulated signal,   The first spectrum of the modulated signal coupled to the transmission channel A first demodulator (50, 100) for demodulating the components,   The second spectrum of the modulated signal coupled to the transmission channel A second demodulator for demodulating the component,   A signal coupled to the first and second demodulators is provided to represent the data signal. A subtractor (60, 70) that Data transmission system equipped with. 2. The modulator (20) produces the FM-modulated first and second spectral components. And   Each of the first and second modulators (50, 100) is a phase locked loop FM detector. Including vessels,   Each of the phase-locked loop FM detectors is   It has a first input terminal that responds to the transmitted modulated signal and a second input terminal. A phase detector (52, 102) for   A loop filter coupled to the phase detector for producing a demodulated data signal (54, 104),   Above the phase detector and the frequency control input terminal coupled to the loop filter A voltage controlled oscillator (56,10) having an output terminal coupled to the second input terminal. 6), The data transmission system according to claim 1, comprising: 3. The modulator (20) includes a first FM modulation spectrum centered on a first frequency. And a second FM modulation spectrum component centered around the second frequency. Produces   The center frequency of the voltage controlled oscillator (56, 106) of the first demodulator is Is the first frequency,   The center frequency of the voltage controlled oscillator (56, 106) of the second demodulator is The second frequency, The data transmission system according to claim 2. 4. A low pass coupled to the subtractor for passing a signal representative of the data signal. The data transmission system according to claim 1, further comprising a pass filter (80, 90). Tem. 5. The transmission coupled between the transmission channel and the first and second demodulators. The transmitted spectral component of the transmitted signal is divided between the first and second intermediate portions, respectively. A down converter (20 ') for converting the frequency and a converter for converting the transmitted signal. A bandpass filter having a passband for passing the exchanged first and second spectral components. Data transmission system according to claim 1, further comprising a series connection with a filter (40). Tem. 6. The modulator (20) is a frequency control input coupled to the source of the data signal. Comprising a voltage controlled rectangular wave oscillator (10) having a force terminal, the modulator (20) comprising: Further comprising an upconverter coupled to the above rectangular wave oscillator, Item 2. The data transmission system according to Item 1. 7. A first spectral component representing the data signal and 18 for the data signal A signal of a modulation signal having a second spectral component representing a signal that is 0 ° out of phase Source (35),   A first demodulator (50, 1) for demodulating the first spectral component of the modulated signal. 00),   A second demodulator (50, 1) for demodulating the second spectral component of the modulated signal. 00),   Generating a signal representative of the data signal in response to the first and second demodulators. A subtractor (60, 70), A data receiver equipped with. 8. The signal source is   In response to the first and second spectral components of the modulated signal, the modulated signal of the modulated signal Convert the first and second spectral components to respective first and second intermediate frequencies Down converter (20 '),   A first converted signal of the modulated signal coupled to the down converter, And a band pass filter (40) having a pass band for passing the second spectral component )When, The data receiver according to claim 7, which comprises: 9. The signal source (35) is provided with the first and second blocks of the FM-modulated modulated signal. Generate a vector component,   Each of the first and second demodulators (50, 100) includes a phase locked loop FM detector. Including a wave instrument,   The phase locked loop FM detector is   A first input terminal coupled to the bandpass filter (40) and a second input terminal A phase detector (52, 102) having a child,   Is coupled to the phase detector (52, 102) and produces a demodulated data signal. Loop filter (54, 104)   Above the phase detector and the frequency control input terminal coupled to the loop filter A voltage controlled oscillator (56,10) having an output terminal coupled to the second input terminal. 6), Consists of   The center frequency of the voltage controlled oscillator of the first demodulator is the first frequency. And   The center frequency of the voltage controlled oscillator of the second demodulator is the second frequency. , The data receiver according to claim 8. 10. A first spectral component of a modulated signal representative of a data signal and said data signal A second spectral component of the modulated signal, which represents a signal that is 180 ° out of phase with respect to A data transmitter for generating minutes and   A signal source (5, 25) for the data signal,   Voltage controller having a frequency control input terminal coupled to a source of the data signal A square wave oscillator (10), A data transmitter equipped with. 11. The up converter (20) coupled to the rectangular wave oscillator (10) is further To   The upconverter is   A local oscillator (30) on the transmitter side,   Coupled to the square wave oscillator (10) and the local oscillator (30), A mixer (20) for producing the first and second spectral components of the modulated signal; Including The data transmitter according to claim 10. 12. A signal source (5, 25) for the first data signal,   A signal source (5, 25) for the second data signal,   Combining the first and second data signals in response to the first and second data signals. For the first modulated signal, the second data signal, and the first data signal. To generate a second modulated signal that represents a combination with a signal that is 180 ° out of phase. A controller (20),   A transmission channel for transmitting the first and second combined modulated signals;   The transmitted first combined modulated signal coupled to the transmission channel A first demodulator (50, 100) for demodulation,   The transmitted second combined modulation signal coupled to the transmission channel A second demodulator (50, 100) for demodulation,   A signal representative of the first data signal coupled to the first and second demodulators. A subtractor (60, 70) for generating a signal,   A signal representative of the second data signal coupled to the first and second demodulators. An adder (60, 70) for generating a number, Dual data signal transmission system with. 13. A first modulated signal representing a combination of the first and second data signals and the second data signal. Data signal and a signal that is 180 ° out of phase with the first data signal A signal source (5, 25) with a second modulated signal representing,   A first demodulator (50, 100) for demodulating the first combined modulated signal;   A second demodulator (50, 100) for demodulating the second combined modulated signal;   A signal representative of the first data signal coupled to the first and second demodulators. A subtractor (60, 70) for generating a signal,   A signal representative of the second data signal coupled to the first and second demodulators. An adder (60, 70) for generating a number, A data receiver equipped with. 14． In response to the first and second combined modulated signals, the first and second modulated signals are A down converter (20 ') for converting to a first and a second intermediate frequency, respectively,   Coupled to the downconverter for converting the converted first and second combined variables. A band pass filter (40) having a pass band for passing a tonal signal; 14. The receiver according to claim 13, comprising:

Claims (1)

[Claims] 1. A data signal source (5, 25),   A first modulated signal representative of the data signal in response to the data signal; A second modulated signal representing a signal 180 degrees out of phase with the data signal. With a controller   A transmission channel for transmitting the first and second modulated signals,   Demodulates the transmitted first modulated signal coupled to the transmission channel A first demodulator (50, 100)   Demodulates the transmitted second modulated signal coupled to the transmission channel A second demodulator (50, 100)   A signal coupled to the first and second demodulators is provided to represent the data signal. A subtractor (60, 70) that Data transmission system equipped with. 2. The modulator (20) generates the FM-modulated first and second modulated signals,   Each of the first and second modulators (50, 100) is a phase locked loop FM detector. Including vessels,   Each of the phase-locked loop FM detectors is   It has a first input terminal that responds to the transmitted modulated signal and a second input terminal. A phase detector (52, 102) for   A loop filter coupled to the phase detector for producing a demodulated data signal (54, 104),   Above the phase detector and the frequency control input terminal coupled to the loop filter A voltage controlled oscillator (56,10) having an output terminal coupled to the second input terminal. 6), The system of claim 1, wherein the system comprises: 3. The modulator (20) includes the first FM modulated signal centered on a first frequency. And a second FM modulated signal centered around a second frequency,   The center frequency of the voltage controlled oscillator (56, 106) of the first demodulator is Is the first frequency,   The center frequency of the voltage controlled oscillator (56, 106) of the second demodulator is The system of claim 2, wherein the system is at a second frequency. 4. A low pass coupled to the subtractor for passing a signal representative of the data signal. The system of claim 1, further comprising a pass filter (80, 90). 5. The transmission coupled between the transmission channel and the first and second demodulators. Converts the transmitted first and second modulated signals to respective first and second intermediate frequencies A down converter (20 ') passes through the converted first and second modulated signals. Further comprising a series connection with a bandpass filter (40) having a passband to The system of claim 1. 6. The modulator (20) is a frequency control input coupled to the source of the data signal. A voltage controlled rectangular wave oscillator (10) having a force terminal, the modulator (20) comprising: The method of claim 1, further comprising an upconverter coupled to the square wave oscillator. System listed. 7. The first modulated signal representing the data signal and 180 ° away from the data signal A source (35) with a second modulated signal representing the phased signal,   A first demodulator (50, 100) for demodulating the first modulated signal;   A second demodulator (50, 100) for demodulating the second modulated signal;   Generating a signal representative of the data signal in response to the first and second demodulators. A subtractor (60, 70), A data receiver equipped with. 8. The signal source is   Responsive to the first and second modulated signals, the first and second modulated signals, respectively. A down converter (20 ') for converting the first and second intermediate frequencies of   Coupled to the down converter for converting the converted first and second modulation signals A band pass filter (40) having a pass band for passing the signal, The receiver according to claim 7, which comprises: 9. The signal source (35) produces the first and second FM modulated signals,   Each of the first and second demodulators (50, 100) includes a phase locked loop FM detector. Including a wave instrument,   The phase locked loop FM detector is   A first input terminal coupled to the bandpass filter (40) and a second input terminal A phase detector (52, 102) having a child,   Is coupled to the phase detector (52, 102) and produces a demodulated data signal. Loop filter (54, 104)   Above the phase detector and the frequency control input terminal coupled to the loop filter A voltage controlled oscillator (56,10) having an output terminal coupled to the second input terminal. 6), Consisting of   The center frequency of the voltage controlled oscillator of the first demodulator is the first frequency. And   The center frequency of the voltage controlled oscillator of the second demodulator is the second frequency. , The receiver according to claim 8. 10. A first modulated signal representing a data signal and 180 ° to the data signal A data transmitter for generating a second modulated signal representative of the phase separated signals,   A signal source (5, 25) for the data signal,   A voltage controlled quadrature having a frequency controlled input terminal coupled to the source of the data signal. A waveform oscillator (10), A data transmitter equipped with. 11. The up converter (20) coupled to the rectangular wave oscillator (10) is further To   The upconverter is   A transmitter local oscillator (30),   Coupled to the square wave oscillator (10) and the local oscillator (30), A mixer (20) for generating first and second modulated signals, The transmitter according to claim 10, which comprises: 12. A signal source (5, 25) for the first data signal,   A signal source (5, 25) for the second data signal,   Combining the first and second data signals in response to the first and second data signals. For the first modulated signal, the second data signal, and the first data signal. And a second modulated signal that represents a combination with a signal that is 180 degrees out of phase (20)   A transmission channel for transmitting the first and second combined modulated signals;   The transmitted first combined modulated signal coupled to the transmission channel A first demodulator (50, 100) for demodulation,   The transmitted second combined modulation signal coupled to the transmission channel A second demodulator (50, 100) for demodulation,   A signal representative of the first data signal coupled to the first and second demodulators. A subtractor (60, 70) for generating a signal,   A signal representative of the second data signal coupled to the first and second demodulators. An adder (60, 70) for generating a number, Dual data signal transmission system with. 13. A first modulated signal representing a combination of the first data signal and the second data signal; A signal that is 180 degrees out of phase with the second data signal and the first data signal; A source (5, 25) with a second modulated signal representing the synthesis of   A first demodulator (50, 100) for demodulating the first combined modulated signal;   A second demodulator (50, 100) for demodulating the second combined modulated signal;   A signal representative of the first data signal coupled to the first and second demodulators. A subtractor (60, 70) for generating a signal,   A signal representative of the second data signal coupled to the first and second demodulators. An adder (60, 70) for generating a number, A data receiver equipped with. 14． In response to the first and second combined modulated signals, the first and second modulated signals are A down converter (20 ') for converting each of the first and second intermediate frequencies,   Coupled to the downconverter for converting the converted first and second combined variables. A band pass filter (40) having a pass band for passing a tonal signal; 14. The receiver according to claim 13, comprising: